Abstract: Methods and systems are disclosed that facilitate formation of dielectric layers having a particular composition profile by forming the dielectric layer as a number of sub-layers. The sub-layers are thin enough so that specific relative compositions can be achieved for each layer and, therefore, the sub-layers collectively yield a dielectric layer with a particular profile. The formation of individual sub layers is accomplished by controlling one or more processing parameters for a chemical vapor deposition process that affect relative compositions. Some processing parameters that can be employed include wafer temperature, pressure, and precursor flow rate.

Abstract: Semiconductor devices (102) are presented along with fabrication methods (202) therefor, in which a conductive contact structure (116b) is formed with a lower contact surface (116c) having a lateral contact dimension (152), where the contact structure (116b) is at least partially coupled with a contact landing surface of a polysilicon structure (110) having a lateral contact landing surface dimension (150) that is less than about 140% of the lateral contact dimension (152) of the conductive contact structure (116b).

Abstract: The present invention facilitates semiconductor fabrication by providing methods of fabrication that mitigate leakage and apply strain to channel regions of transistor devices. A semiconductor device having gate structures, channel regions, and active regions is provided (102). Extension regions of a first type of conductivity are formed within the active regions (104). Recesses are then formed within a portion of the active regions (106). Second type recess structures are formed (108) within the recesses, wherein the second type recess structures have a second type of conductivity opposite the first type and are comprised of a strain inducing material. Then, first type recess structures are formed (110) within the recesses and on the second type recess structures, wherein the first type recess structures have the first type of conductivity and are comprised of a strain inducing material.

Abstract: The present invention pertains to formation of a PMOS transistor wherein a layer of silicon or SiGe inhibits p-type dopant from entering into an underlying gate dielectric layer. The p-type dopant can be added to a gate electrode material that overlies the silicon or SiGe layer and can diffuse down toward the silicon or SiGe layer. The layer of silicon or SiGe may be formed to a thickness of about 5 to 120 nanometers and doped with a dopant, such as indium (In), for example, to deter the p-type dopant from passing through the silicon or SiGe layer. The dopant may have a peak concentration within the layer of silicon or SiGe near the interface of the silicon or SiGe layer with the underlying layer of gate dielectric material. Allowing the gate electrode to be doped with the p-type dopant (e.g., boron) facilitates forming the transistor with an associated work function having a desired value (e.g., coincident with a Fermi level of about 4.8 to about 5.6 electron volts).

Abstract: One or more aspects of the present invention relate to forming a transistor while passivating electrically active defects associated with a top portion of a layer of high-k dielectric material. The layer of high-k dielectric material is utilized to establish a high-k gate dielectric in the transistor. A gate electrode layer is formed over the layer of high-k dielectric material, and is patterned to form a gate structure that includes a gate electrode and the high-k gate dielectric. The electrically active defects are passivated utilizing materials containing dopants that are attracted to and neutralize the defects. The passivated defects thus do not interfere with other transistor doping processes (e.g., forming source and drain regions) and do not adversely affect resulting semiconductor device performance, reliability and yield.

Abstract: The present invention pertains to formation of a PMOS transistor wherein a layer of silicon or SiGe inhibits p-type dopant from entering into an underlying gate dielectric layer. The p-type dopant can be added to a gate electrode material that overlies the silicon or SiGe layer and can diffuse down toward the silicon or SiGe layer. The layer of silicon or SiGe may be formed to a thickness of about 5 to 120 nanometers and doped with a dopant, such as indium (In), for example, to deter the p-type dopant from passing through the silicon or SiGe layer. The dopant may have a peak concentration within the layer of silicon or SiGe near the interface of the silicon or SiGe layer with the underlying layer of gate dielectric material. Allowing the gate electrode to be doped with the p-type dopant (e.g., boron) facilitates forming the transistor with an associated work function having a desired value (e.g., coincident with a Fermi level of about 4.8 to about 5.6 electron volts).

Abstract: The present invention pertains to formation of a PMOS transistor wherein a layer of silicon or SiGe inhibits p-type dopant from entering into an underlying gate dielectric layer. The p-type dopant can be added to a gate electrode material that overlies the silicon or SiGe layer and can diffuse down toward the silicon or SiGe layer. The layer of silicon or SiGe may be formed to a thickness of about 5 to 120 nanometers and doped with a dopant, such as indium (In), for example, to deter the p-type dopant from passing through the silicon or SiGe layer. The dopant may have a peak concentration within the layer of silicon or SiGe near the interface of the silicon or SiGe layer with the underlying layer of gate dielectric material. Allowing the gate electrode to be doped with the p-type dopant (e.g., boron) facilitates forming the transistor with an associated work function having a desired value (e.g., coincident with a Fermi level of about 4.8 to about 5.6 electron volts).

Abstract: Methods are presented for fabricating MOS transistors, in which a sacrificial material such as silicon germanium is formed over a gate contact material prior to gate patterning. The sacrificial material is then removed following sidewall spacer formation to provide a recess at the top of the gate structure. The recess provides space for optional epitaxial silicon formation and suicide formation over the gate contact material without overflowing the tops of the sidewall spacers to minimize shorting between the gate and the source/drains in the finished transistor.

Abstract: The present invention pertains to formation of a PMOS transistor wherein a layer of silicon or SiGe inhibits p-type dopant from entering into an underlying gate dielectric layer. The p-type dopant can be added to a gate electrode material that overlies the silicon or SiGe layer and can diffuse down toward the silicon or SiGe layer. The layer of silicon or SiGe may be formed to a thickness of about 5 to 120 nanometers and doped with a dopant, such as indium (In), for example, to deter the p-type dopant from passing through the silicon or SiGe layer. The dopant may have a peak concentration within the layer of silicon or SiGe near the interface of the silicon or SiGe layer with the underlying layer of gate dielectric material. Allowing the gate electrode to be doped with the p-type dopant (e.g., boron) facilitates forming the transistor with an associated work function having a desired value (e.g., coincident with a Fermi level of about 4.8 to about 5.6 electron volts).

Abstract: Methods and systems are disclosed that facilitate formation of dielectric layers having a particular composition profile by forming the dielectric layer as a number of sub-layers. The sub-layers are thin enough so that specific relative compositions can be achieved for each layer and, therefore, the sub-layers collectively yield a dielectric layer with a particular profile. The formation of individual sub layers is accomplished by controlling one or more processing parameters for a chemical vapor deposition process that affect relative compositions. Some processing parameters that can be employed include wafer temperature, pressure, and precursor flow rate.

Abstract: One or more aspects of the present invention relate to forming a transistor while passivating electrically active defects associated with a top portion of a layer of high-k dielectric material. The layer of high-k dielectric material is utilized to establish a high-k gate dielectric in the transistor. A gate electrode layer is formed over the layer of high-k dielectric material, and is patterned to form a gate structure that includes a gate electrode and the high-k gate dielectric. The electrically active defects are passivated utilizing materials containing dopants that are attracted to and neutralize the defects. The passivated defects thus do not interfere with other transistor doping processes (e.g., forming source and drain regions) and do not adversely affect resulting semiconductor device performance, reliability and yield.

Abstract: Methods are provided for fabricating a transistor gate structure in a semiconductor device, comprising growing an interface oxide layer to a thickness of about 18 Å or less over a semiconductor body using an oxidant comprising N2O and hydrogen or NO and hydrogen at a temperature of about 800 degrees C. or more and a pressure of about 200 Torr or less. A high-k dielectric layer is formed over the interface oxide layer, and a gate contact layer is formed over the high-k dielectric layer. The gate contact layer, the high-k dielectric layer, and the interface oxide layer are then patterned to form a transistor gate structure.

Abstract: Methods are disclosed for fabricating transistor gate structures and high-k dielectric layers therefor by sputter deposition, in which nitridation and/or oxidation or other adverse reaction of the semiconductor material is reduced or minimized by reducing the bombardment of the semiconductor body by positively charged reactive ions such as oxygen ions or nitrogen ions during the sputter deposition process. The sputtering operation may be a two-step process in which ionic bombardment of the semiconductor material is minimized in an initial deposition step to form a first layer portion covering the semiconductor body, and the second step completes the desired high-k dielectric layer. Mitigation of unwanted nitridation and/or oxidation or other adverse reaction is achieved through one, some, or all of high sputtering deposition pressure, repulsive wafer biasing, increased wafer-plasma spacing, low partial pressures for reactant gases, and low sputtering powers or power densities.

Abstract: Methods are disclosed for forming gate dielectrics for MOSFET transistors, wherein a bilayer deposition of a nitride layer and an oxide layer are used to form a gate dielectric stack. The nitride layer is formed on the substrate to prevent oxidation of the substrate material during deposition of the oxide layer, thereby avoiding or mitigating formation of low-k interfacial layer.

Abstract: A luminous phosphorescent color monitoring system build into or added to a cloth or disposable absorbent diaper or any personal hygiene utensil to confirm the state of the apparatus. The functioning bright color indicating system is also detectable in the dark and develops when body secretions are effecting the apparatus and the built in system registers the interface of the natural human secretions which catalyst and develops the positive visual format on the outer stratified layer of the utensil. The functioning pigments are water compatible, non toxic or detrimental to humans and calls for the observance of a bright luminous color emitted mostly in the inner surface of the outer layer of a diaper liner or commercially available pamper.

Abstract: One aspect of the invention relates to a method of etching a high-k dielectric. The method involves removing an exposed portion of a high-k dielectric layer from a substrate by wet etching with a solution comprising water, a strong acid, an oxidizing agent, and a fluorine compound. The etching solution provides selectivity towards the high-k film against insulating materials and polysilicon and is therefore useful in manufacturing FETs.

Abstract: Methods are disclosed for forming gate dielectrics for MOSFET transistors, wherein a bilayer deposition of a nitride layer and an oxide layer are used to form a gate dielectric stack. The nitride layer is formed on the substrate to prevent oxidation of the substrate material during deposition of the oxide layer, thereby avoiding or mitigating formation of low-k interfacial layer.

Abstract: One aspect of the invention relates to a method of etching a high-k dielectric. The method involves removing an exposed portion of a high-k dielectric layer from a substrate by wet etching with a solution comprising water, a strong acid, an oxidizing agent, and a fluorine compound. The etching solution provides selectivity towards the high-k film against insulating materials and polysilicon and is therefore useful in manufacturing FETs.

Abstract: An electrical power plant has a rotator means (1) that rotates one or more alternators (6, 8) to generate electrical current that is transmitted to one or more electrical storage bakeries (12, 13) from which electrical current is transmitted to an electrical motor (2) that is a rotational-power component of the rotator means. Electrical current can be transmitted from the one-or-more storage batteries to electrical items such as a vehicle motor (32, 34), electrical appliances, electric lights and electrical communication devices. The rotator means can include a prime mover (10) that can be used for particular applications such as a vehicle (30) engine in addition to rotation of one or more of the alternators.